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18/4/2004 - Ha Huu 

Hoi cac ban nong dan, tai sao den bay gio toi chua thay ai tham gia vao viec so sanh giua cac loai mat tiet trung nuoc vay.

Xin hoi y cua Viet Linh the nao

Cong ty SX may OZONE va cac nha sx may dien giai va UV nhu the nao?

Rat mong duoc tra loi


Vừa qua chúng tôi nhận được nhiều bài viết về các loại máy trên, các bài viết đều nêu lên cái tốt của chủng loại máy, nhưng cái bà con nông dân và các nhà đầu tư nuôi trồng thủy sản cần chưa đề cập nhiều, mặt khác tiêu chí Việt Linh đề ra có khác là: Mỗi loại máy đều có ưu và khuyết điểm, nhưng chung quy máy phải ứng dụng được cho bà con và mang lại hiệu qủa thực sự, bền, dễ sử dụng, đặc biệt là được nhiệt đới hóa, các bản so sánh sau khi kiểm tra xác nhận về khả năng diệt khuẩn trong nước, kết qủa và ưu thế cạnh tranh giữa các loại.

Hiện nay cái cần là quy trình xử lý nước trước, trong và sau khi nuôi của loại thiết bị đó có đáp ứng được yêu cầu hay không và kết qủa thu hoạch vụ nuôi, nghĩa là bằng thực nghiệm thuyết phục.

Rất mong các bạn cùng tham gia thảo luận

www.vietlinh.com.vn


6/4/2004 - Tường Lân

Introduction

Gaseous ozone, formed photochemically in the earth's atmosphere by radiation from the sun, is a normal constituent of the earth's atmosphere which is important in shielding the earth from cancer-causing ultraviolet radiation emitted by the sun. Large scale generation of ozone is extremely important commercially, however, due to its strong oxidizing abilities.

figure 1: ozone's strong oxidizing ability

The word for ozone comes from the Greek word "ozein" which means "to smell" since ozone was first noticed because of its characteristic pungent odor (1). The odor is detectable in air at levels of about 0.1 parts per million, and exposure to ozone becomes fatal to humans at around levels of 100 ppm for 10,000 minutes or 10,000 ppm for 30 seconds (2). Ozone, O3, is a blue-colored gas at ambient temperatures, but this color is not noticed at the low concentrations at which it is usually generated (2). In the liquid and solid states, ozone is dark blue. Liquid ozone boils at -111.3 °C and solid ozone melts at -192.5 °C (3). Ozone, which is toxic, is an unstable gas and an explosive liquid. The ozone molecule is a bent molecule with an O-O bond length of 1.278 A and a bond angle of 116.8° as shown in the diagram below (3)

figure 2

Second only to fluorine in its oxidizing power, ozone has many uses including but not limited to water purification, bleaching of materials such as paper, synthetic fibers, Teflon, waxes, flour, and other products, treatment of wastes in industry, deodorization and sterilization (3). Previously, chlorine products have been used for these purposes, but recent studies have shown that chlorine products may produce carcinogens such as trihalomethanes and chloramines (4). Ozone is a safe alternative to chlorine products which performs the same functions without the undesirable side effects; it is not harmful to the environment since it is made from oxygen (O2) and decomposes back into O2. Perhaps the most common use of commercially produced ozone is in treatment of water and wastewater. Ozone has been used in water treatment worldwide for more than 100 years (2).

Drinking water, when untreated, often contains undesirable sediments, unwanted colors, and residual tastes and odors which may be successfully removed by treatment with ozone. Treatment of drinking water with ozone disinfects the water by killing bacteria and inactivating viruses present in the water; ozone has been shown to effectively inactivate strains of poliovirus, adenoviruses, rotaviruses, and the viruses which cause vesicular stomatitis and encephalomyocarditis (4). The oxidative properties of ozone are useful in the removal of soluble iron and manganese, the removal of unwanted colors, tastes, and odors, the decomplexing of bound heavy metals, the destruction of inorganic components such as sulfides, cyanides, and nitrites, and the removal of suspended solids (2). One invention even provides a means for maintaining a degree of residual ozone in the water after treatment so that the water will remain pure during storage (5).

wastewaters associated with pulp and paper mills, and waters polluted with pesticides. The primary application of ozone in sewage treatment is disinfection, but it is also used to control odor, to aid in removal of suspended solids, and to improve the biodegradability of the wastewater (6). An advantage of ozonation of sewage is that it reduces levels of suspended solids in the effluent without the addition of dissolved chemicals, it removes viruses effectively, and it is cost-effective compared to alternate forms of treatment (2).

In the paper production industry, ozone has recently been widely considered as a method of treating pulp and paper wastewaters. These toxic wastewaters typically have high concentrations of organochlorine compounds such as chlorphenolic compounds, chloroacetones, and chloroform and are highly colored; these organochlorine compounds and colored compounds are resistant to conventional methods of treatment (6). Studies have shown that ozone is a viable alternative to chlorine-based bleaching chemicals which is effective in significantly reducing levels of organochlorines, colors, and toxicity levels in pulp and paper wastewaters. Elemental chlorine, which is usually used in pulp bleaching processes, is an effective bleaching agent but is potentially dangerous because the effluents from chlorine-based bleaching processes contain chloride by-products which are corrosive to processing equipment and which are toxic to humans and animals (7).

Industry holds several patents on environmentally improved methods of bleaching pulp with ozone. Among these patents are US Patent #5,164,043, US Patent #5,520,783, US Patent #5,174,861, and US Patent #5,451,296. Ozone is such a powerful oxidizing agent that in pulp bleaching processes, it not only bleaches the lignin portion of the pulp, but also degrades the cellulose in the pulp (7). Wood is made up of two main components, a cellulosic portion and lignin (7). The lignin portion of wood is ideally destroyed in pulp bleaching processes, but the cellulosic portion of wood gives pulp its strength, and therefore should not be attacked by the bleaching agent (8). In order to prevent the problem of ozone attacking the cellulosic portion of pulp, the processes outlined in some patents involve using ozone as a third step in the bleaching treatment under selectively defined and carefully controlled parameters (pH control, use of chelating agents for metal ion control, pulp consistency) so that the ozone minimally degrades the cellulosic portion of the pulp (7).

Although many methods exist for producing ozone, there are three main categories of methods of ozone production, corona discharge methods, electrochemical methods, and methods involving ultraviolet radiation. In the corona discharge method, by far the most common method, oxygen or an oxygen-containing gas, most commonly air, is passed through the space between two electrodes separated by a dielectric material which is usually glass (Figure 2). The electrodes are most often either concentric metallic tubes or flat, plate-like electrodes which are connected to a source of high voltage. When a voltage is supplied to the electrodes, a corona discharge forms between the two electrodes, and the oxygen in the discharge gap is converted to ozone. A corona discharge is a physical phenomenon characterized by a low-current electrical discharge across a gas-containing gap at a voltage gradient which exceeds a certain critical value (9). First, oxygen molecules, O2, are split into oxygen atoms, O, and then the individual oxygen atoms combine with remaining oxygen molecules to form ozone, O3.

The corona discharge generates heat which causes the produced ozone to decompose into oxygen atoms and molecules. In order to prevent this decomposition, ozone generators which utilize the corona discharge method must be equipped with a means of cooling the electrodes. The temperature of the gas inside the discharge chamber must be maintained at a temperature between the temperature necessary for formation of ozone to occur and the temperature at which spontaneous decomposition of ozone occurs. This necessary cooling is usually accomplished by circulating a coolant such as water or air over one surface of the electrodes so that the heat given off by the discharge is absorbed by the coolant. Many variations of this method have been patented because it produces the highest concentrations of ozone per unit of electrical energy used.

Figure 3: Schematic Diagram of A Typical Corona Discharge Ozone Generator

Usually, in the electrochemical method of ozone production, an electrical current is applied between an anode and cathode in an electrolytic solution containing water and a solution of highly electronegative anions. A mixture of oxygen and ozone is produced at the anode. Another common method of ozone generation involves bombarding oxygen with ultraviolet radiation which splits oxygen molecules into oxygen atoms which combine with other oxygen molecules to form ozone. As with the corona discharge method, many modifications of the electrochemical method of ozone production and the ultraviolet radiation method exist. Many other methods of producing ozone and processes for using ozone generators have been patented.

Ozone, like oxygen, chlorine, and hydrogen peroxide, is a strong oxidizing agent. The relatively high (+2.07V) electrochemical potential indicates a very favorable oxidizing agent. Ozone's widespread application is based on its ability to pull electrons from a covalent bond causing it to break, or pulling electrons from an aqueous phase metal (Fe+2 --> Fe+3) causing it to undergo hydrolysis (Fe+3 --> Fe(OH)3(s)) and precipitate from solution.

O2 + 4H3O+ + 4e- --> 6H2 O

Eo = +1.23 V

Cl2 + 2e- --> 2Cl-

Eo = +1.36 V

HClO + H3O+ + e- --> 2H2O + 1/2Cl2 (g)

Eo = +1.63 V

HClO2 + 2H3O+ + 2e- --> HClO + 2H2O

Eo = +1.63 V

H2O2 + 2H3O+ + 2e- --> 4H2O

Eo = +1.77 V

O3(g) + 2H+ + 2e- --> O2(g) + H2O

Eo = +2.07 V

F2 + 2e- --> 2F-

Eo = +2.87 V

 

The high electrochemical potential shows ozone's favorable thermodynamics. the chart below (from Chemical and Engineering News) illustrates ozone's favorable kinetics as compared to other oxidizing agents. For industrial purposes, whether a reaction takes place in seconds, minutes, or days is of tremendous importance.

 

COMPOUND

CHLORINE

PERMANGANATE

OZONE

 Acetophenone

26 days

43 days

25 minutes

Benzaldehyde

>3.2 days

36 minutes

28 minutes

Camphor

>3.2 days

>5.8 days

12 minutes

p-nitrophenol

2.1 hours

1.1 days

2 minutes

borneol

1.4 days

7 days

53 minutes

methyl-m-toluate

>20 days

22 days

5.5 minutes

diacetone-L-sorbose

100 days

14 days

2.8 minutes

 


20/3/2004 - Doan Ngoc Huu - Toi rat vui vi co nguoi dong hanh trao doi nhung kinh nghiem ma chung ta co duoc qua cac tai lieu, hy vong tu day moi nguoi cung quan tam den muc thu tu nay. Toi xin thong tin them voi anh ve the Oxi hoa cua khi ozon de chung ta tu lam phep so sanh, day cung la tai lieu ma toi thu thap duoc tai mang website: http:// www.int-ozone-assoc

Ozone vs. Chlorine:

ACTION IN WATER

  CHLORINE

  OZONE

Oxidation Potential (Volts)-

1.36

2.07

Disinfection:
Bacteria
Viruses


Moderate
Moderate


Excellent
Excellent

Environmentally Friendly

No

Yes

Color Removal

Good

Excellent

Carcinogen Formation

Likely

Unlikely

Organics Oxidation

Moderate

High

Micro flocculation

None

Moderate

pH Effect

Variable

Lowers

Water Half-Life

2-3 hours

20 min.

Operation Hazards:
Skin Toxicity
Inhalation Toxicity


High
High


Moderate
High

Complexity

Low

High

Capital Cost

Low

High

Monthly Use Cost

Moderate-High

Low

Air Pre-treatment

None

Filer and dehumidify air

 

Tu day toi chi nghi rang neu may dien giai co the tao ra ozon duong va am thi khong co ly do gi ma khong san xuat ra may ozon vi chac chan no tot hon nhieu.

Sau day la mot so tai lieu nguyen van ma toi lay duoc, mong moi nguoi cung nhau tham khao:

Shrimp Farms

Ozone is the second most powerful oxidizer, falling only behind Fluorine. Residual amounts of dissolved organic compounds can be removed by oxidation. Ozone is a very unstable molecule which will, in water, very rapidly self-decompose into oxygen from which it was formed and leave no hazardous by-products as does chlorine, the most widely used oxidizer. Residual amounts of ozone can be removed from the water prior to consumption by passing the water through a UV chamber, and/or an activated charcoal filter.

Therefore it has the power and ability to destroy all types of microorganisms. In fact, no microorganism is known to be resistant to ozone. Are a exspensive business and are highly volitile in respect of losing the crop. From one unfortunate mistake of the water not being treated properly can result in the loss of thousands of dollars.With implementing a Ozone system you can ensure the success of your crop! Using Ozone you can prevent the risk of Legionnaire, increase the D.O Level of oxygen at night-time to assist in the aerobic fermentation process, remove all toxic chemicals such as chlorine and formaldehyde, it will remove all anaerobic gases in the water and all micro-organisms. With Ozzonics closed loop system this stops all risk of water from outside which is not treated and is a threat to the loss of a crop. One set can be used for 2 ponds which also reduces operating costs. Ozone is a natural disenfectant that kills all bacteria, it also purifies water 3000 times faster than chlorine and reverts back to pure oxygen if un-needed.